Identificador: TDX:4144
Autores: Garay Ruiz, Diego
Resumen:
The molecular-level insights gathered through 'in silico' studies have become an essential asset for the elucidation
and understanding of complex reaction mechanisms. Indeed, the applicability of computational chemistry has strongly
widened due to the vast increase in computational power along the last decades. In this sense, not only the accuracy
of the applied methods or the size of the target systems have increased, but also the level of detail attained for the
mechanistic description. However, performing deeper descriptions of chemical systems, most often resorting to
automation techniques that allow to easily explore larger parts of the chemical space, comes at the cost of also
augmenting their complexity, rendering the results much harder to interpret. Throughout this Thesis, we have
proposed, developed and tested a collection of tools aiming to process this kind of complex chemical reaction
networks (CRNs), in order to provide new insights on reactive and catalytic processes. All of these tools employ
graphs to model the target CRNs, in order to be able to use the methods of Graph Theory (e.g. path searches,
isomorphisms...) in a chemical context. The tools that are discussed include amk-tools, a framework for the interactive
visualization of automatically discovered reaction networks, gTOFfee, for the application of the energy span model to
compute the turnover frequency of computationally characterized catalytic cycles, and OntoRXN, an ontology for the
description of CRNs in a semantic manner integrating network topology and calculation information in a single,
highly-structured entity.
Repositori URV